NO844336L - CONTROL SYSTEM - Google Patents

Description

The present invention relates to a control system, mainly for electrical equipment in building technology, e.g. equipment to control several electric heating devices.

The electric heating systems that are currently in use in buildings and apartments are based on each individual electric heating device, i.e. separate control of a radiator, usually by means of a thermostat. The heating device is then switched on at full power, until a set temperature is reached and the thermostat switches off the heat. The power is switched on again after a time, when the temperature has fallen below the set value.

There are some serious drawbacks to this conventional control system. The surface temperature of the electric firing equipment and radiators tends to be very high during the firing period; if the thermostat e.g. is arranged under a curtain or if clothes are placed to dry on the radiator, there may even be a fire hazard.

Furthermore, said heating device is uneconomical due to its high surface temperature. The heating does not register in any way the outside temperature or temporary ventilation and other special conditions that can momentarily cause a rapid and often unnecessary change in the heating effect.

Furthermore, the regulation of simultaneously acting electric heating devices is insufficiently designed today. When several heating devices work at the same time, their peak power consumption is high and this must be taken into account in connection with the supply network and this requires additional expenses in connection with electrical power reserves.

In addition, conventional control systems for electric firing are different in construction and mode of operation, so that each operation generally has its own, separate control system, which is independent of the other equipment.

This entails increased expenses in connection with the construction of control systems and also practical inconveniences.

The purpose of the present invention is to eliminate them

the above disadvantages. A particular purpose of the invention is to provide a control system, which makes it possible to design equipment for several electrical devices, especially devices for building technology and especially control of electric heating equipment with electric heating devices in a centralized, efficient and economically advantageous way. Another purpose of the invention is to provide a new type of control system which is operationally reliable, inexpensive to acquire and easy to maintain for control of the relevant equipment.

The features that characterize the invention are stated in the subsequent claims.

The invention is based on a system that is controlled by a host computer and where each individual electrical device is controlled by a controlled computer with a special, chain-like connection mode. According to the invention, the data channel, i.e. the control line, goes from the host computer, through all controlled computers, i.e. from the host computer to the first controlled computer, on to the next computer and on to the next computer, etc., where the controlled computers are arranged to control/control, for example, the current, appropriately the firing current supply to each individual firing device under the control of the host computer. This type of chain matching and grouping between host computer and controlled computers enables automatic coding of the controlled computers, ie numbering of the computers for communication with the host computer according to the program. At the same time, the installation of the managed computers and their mutual connection is carried out correctly at all times; a special data channel number code for the relevant host computer is not required. The controlled computers can further be connected in any order to the host computer.

The control system according to the invention allows, for example,

centralized setting and monitoring of the heating flow. The system also makes it possible, for example, to heat up a temperature-sensitive area in the room and thus precise, room-oriented control. Furthermore, the system provides centralized measurement of the power consumption and observation and monitoring of the output. Furthermore, made-to-order, maximum power-supplied installation and operation is provided in each of the electrical elements, while taking into account the total power demand and the capacity of the electrical network.

In what follows, the invention will be described in detail with reference to some design examples and the attached drawing, where

fig. 1 illustrates one of the applications of the control system according to the invention.

In fig. 1 shows the electric heating equipment, of which only the first three electric heating devices 1, 2, 3 are illustrated. The control system comprises the host computer 10 and the

controlled computers 11, 12, 13, which are arranged to control each of the firing devices 1, 2, 3. The data channel 14, i.e. the control line pair, connects the host computer 10 with the first controlled computer 11 and further with the second controlled computer 12, which is mentioned above as follows after the first and on to the next control computer 13. The data channel 14 thus goes from the host computer 14 in chain fashion through all controlled computers 11, 12, 13.

The controlled computers 11, 12, 13 are arranged to control the supply of firing current 16 from the electrical network to each of the aforementioned firing devices under the control of the host computer. Each of the heating devices 1, 2, 3 is further equipped with temperature sensors 4, 5, 6 which measure the surface temperature of the heating device and temperature sensors 7, 8, 9 which measure said room temperature. The room temperature sensors are located separately from the heating device, so that the signals that the temperature sensors emit to the controlled computers correspond to the actual temperature in the room in question. In the application shown here, the first controlled computer 11 is additionally equipped with a thermostat 50 and its control potentiometer 51 for regulating the room temperature. The host computer 10 comprises an external sensor 15 which measures the external temperature.

In fig. 1, the controlled computer 23 is also connected to the third firing device 3 by means of the control channel 17. The controlled computer 13 controls the firing device 3 and

the controlled heating device 2 3 with the data received by sending surface temperatures from the sensors 6, 29 and by checking the host computer 10.

In the system according to the invention as shown in the figure, the host computer 10, after the system has been linked together, will code the controlled computers 11, 12, 13 for each firing device 1, 2 and 3, so that the number of the first controlled computer 11

e.g. is I, the number of second controlled computer 12 is II, the number of third controlled computer 13 is III, and so on. Then the orders given to each controlled computer 11, 12, 13 are coded with corresponding codes I, II, III. Then the host computer runs through all firing devices 1, 2, 3 and connects each of them in turn to full power via corresponding computers 11, 12, 13 and measures the power consumption of each device, so that the firing power is stored in its storage unit.

The control of the firing power of the firing devices 1, 2, 3 is carried out appropriately by controlling the number of half waves that are supplied to the firing device per unit of time. For example, full alternating current at 50 Hz is achieved by sending 100 half-waves per second to the heating device in question, 30% current is achieved by sending 30 half-waves per second to the heating device.

The controlled computer will calculate in its program the total energy consumed by the heating device, e.g. using the formula below.

where is the number of half-waves sent to the heating element, NQ is the total number of half-waves,<p>max the total power, t the total time and E the total energy consumed by the heating element. The ratio N-j^/Nq thus gives the operating power level of the heating element in relation to its total power. If desired, the current consumed by the heating element can also be calculated in the host computer. Recording and monitoring of the flow can conveniently be carried out in the host computer.

In the figure, the controlled computers 11, 12, 13 of the heating devices 1, 2, 3 are arranged so that they provide the surface temperature of the heating devices and the signals corresponding to the relevant room temperatures to the host computer, which in turn is arranged for calculation and transmission to the controlled computers of the internal setting values of the surface temperatures and the maximum power of the heating device. The host computer performs the above calculations of the surface temperature setpoints and the maximum current and takes into account external temperature, room temperature, total current consumption and peak current consumption for each heating device and equipment capacity.

The controlled computers 11, 12, 13 are suitably arranged so that they calculate the total current used by corresponding heating devices. The total power can be calculated at full power consumption for the entire period; the controlled computers are arranged to send the signals corresponding to the calculated total power to the host computer 10. The host computer calculates and outputs the total instantaneous power of the heating equipment and also the total energy. If desired, the host computer can arrange a tape display of each heating element's energy consumption in desired time units, e.g. during one

day, month or a year.

The host computer can further control/manage the firing device using the controlled computers, e.g. by taking into account a daily rhythm; the night temperature can drop 0 - 9°C. Furthermore, the host computer can control the maximum permissible temperature of the heating device surface in each room, e.g. 40°C in a children's room and 80°C in other rooms. The host computer can also register a failure of a heating device, control computer and/or thermostat. Furthermore, the host computer can be programmed to compensate for a rapid temperature change.

The controlled computers can be supplied with a program so that they operate independently, e.g. on a room-oriented temperature setting basis (eg 22°C), if the host computer or data transmission channel fails.

Furthermore, the control system can be equipped with an element and a device for the controlled computer, so that the temperature setting can be read off on the host computer. This facilitates the most accurate installation and regulation of the equipment.

While the host computer and the controlled computers communicate in accordance with computer programs, the controlled computers are suitably configured to return the signals given to the host computer, i.e. control commands. Furthermore, the controlled computers 11, 12, 13 are suitably arranged for output from their own control programs after coding has been carried out and returned, so that the host computer can then give control instructions to the controlled computers, e.g. about room temperature setting, surface temperature setting, setting for power consumption, etc. Furthermore, the host computer is programmed to, according to its program, require measurement data, such as room temperature, surface temperature, heating effect, local temperature setting, etc.

The embodiment is intended as an illustration of the invention without limiting it in any way and the application of the invention can be varied within the scope of the subsequent claims.

Claims (8)

1. Control system for monitoring and controlling equipment consisting of electrical devices (1, 2, 3), to which system belongs a host computer (10) and where each electrical device is mainly equipped with a controlled computer (11, 12, 13 ), which controlled computers are organized to control corresponding electrical devices under the control of the host computer, characterized in that the host computer (10) and the controlled computers (11, 12, 13) are adapted to each other so that the data path (14) runs from the host computer to the first controlled computer, from this to the other controlled computer, from this to the subsequent controlled computer, etc. to each controlled computer through the preceding controlled computer, whereupon each controlled computer is arranged so that it processes the control signals given to it and to the subsequent controlled computer by the host computer and that it provides the control signals intended for them to the subsequent controlled computer and the controlled computers that follows this. 2. Control system as specified in claim 1, characterized in that the system is designed to control building technology equipment consisting of equipment such as electric heating devices (1, 2, 3), when each heating device is mainly equipped with a controlled computer (11, 12, 13). 3. Control system as specified in claim 2, characterized in that a temperature sensor (4, 5, 6) is arranged in each heating device (1, 2, 3) for measuring the surface temperature of the heating device and a temperature sensor (7, 8, 9 ) for measuring the room temperature. 4. Control system as specified in claim 2 or 3, characterized in that the host computer (10) or at least a controlled computer (11) is equipped with an external temperature sensor (15) for measuring the external temperature. 5. Control system as stated in one of claims 2-4, characterized in that the system comprises a controlled firing unit (23) which is connected to a controlled computer (13) by means of data channel (17) transmission, and that the controlled firing unit is equipped with a temperature sensor (29) which measures the surface temperature of the controlled heating unit which is connected to the controlled computer. 6. Control system as indicated in one of the caravans 2-5, characterized in that the controlled computers (11,12,13) are arranged so that they emit signals corresponding to corresponding room temperatures and surface temperatures for corresponding heating devices (1,2,3) to the host computer (10) and that the host computer is arranged to calculate and send setting values and maximum power to the controlled computers. 7. Control system as specified in one of claims 2-6, characterized in that the controlled computers (11,12,13) are arranged to calculate the total power to be used by the corresponding firing device and send a corresponding signal to the host computer. 8. Control system as specified in one of claims 2-7, characterized in that each controlled computer (11,12,13) is arranged so that it controls the corresponding firing device (1,2,3) on the basis of the signals it receives from the independent, corresponding surface temperature sensors (4, 5,6) and from corresponding room temperature sensors (7,8,9), whereupon contact with the host computer is broken.